Methods to diagnose a required regulation of trophoblast invasion

ABSTRACT

Methods are provided for the diagnosis and treatment of patients with increased risk of preeclampsia. The methods involve measuring levels of TGF-β 3 , receptors of cytokines of the TGβ family, or HIF-1α.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.12/252,400, filed Oct. 16, 2008, which is a continuation of U.S. patentapplication Ser. No. 11/043,493, filed Jan. 26, 2005, now U.S. Pat. No.7,445,940, which is a continuation of U.S. patent application Ser. No.10/028,158, filed Dec. 20, 2001, now U.S. Pat. No. 6,863,880, which is adivision of U.S. patent application Ser. No. 09/380,662, filed Dec. 21,1999, now U.S. Pat. No. 6,376,199, which is a National Stage ofPCT/CA98/00180, filed Mar. 5, 1998, which claims the benefit of thepriority of U.S. Provisional Patent Application No. 60/039,919, filedMar. 7, 1997, now abandoned. Each of these applications is herebyincorporated by reference.

BACKGROUND OF THE INVENTION

During placental development the establishment of fetal-maternalinteractions is critical for a successful human pregnancy (1).Abnormalities of placenta formation due to shallow trophoblast invasionhave been linked to preeclampsia and fetal growth restriction (2). Incontrast, uncontrolled trophoblast invasion and abnormal trophoblastgrowth are associated with hydatiform mole and choriocarcinoma. In thecourse of placenta formation, chorionic villous cytotrophoblasts undergotwo morphologically distinct pathways of differentiation. The vastmajority of cytotrophoblasts in both floating and anchoring villi fuseto form the syncytiotrophoblast layer, which permits gas and nutrientexchange for the developing embryo. A small percentage ofcytotrophoblasts in anchoring villi break through the syncytium, atselected sites, and generate columns of non-polarized cells whichmigrate into the endometrium. These extravillous trophoblasts (EVT)invade deeply into the uterus reaching the first third of the myometriumat which point they invade the spiral arteries, replacing theirendothelium and vascular wall. Invasion peaks at 12 weeks of gestationand rapidly declines thereafter, indicating that, unlike tumourinvasion, it is spatially and temporally regulated (3). Trophoblastinvasion in the decidua is accompanied by a complex modulation of thesynthesis and degradation of extracellular matrix (ECM) proteins and inthe expression of adhesion molecules (4-6). Along the invasive pathway,ECM proteins undergo changes in their spatial distribution with loss oflaminin and appearance of fibronectin (3,4). EVT loose the expression ofE-cadherins, responsible for cell-cell adhesion between polarized stemcytotrophoblasts, down-regulate α₆β₄ integrin, a laminin receptor, andacquire α₅β₁ integrin, a fibronectin receptor (7). Once the EVT invadethe endometrium they express the α₁β₁ integrin, a collagen/lamininreceptor. Thus, specific changes in ECM proteins and their receptors areassociated with the acquisition of an invasive phenotype by theextravillous trophoblasts (4).

Preeclampsia occurs in 5-10% of pregnancies and is the leading cause ofdeath and illness in women during pregnancy. Preeclampsia is alsoassociated with considerable fetal/neonatal complications because ofadverse intrauterine conditions and preterm delivery. There is currentlyno effective pharmacologic treatment for preeclampsia and the onlyremedy is to remove the placenta (and hence deliver the fetus preterm).Current protocols, including bedrest and antihypertensive drugs, seek tostabilize maternal/fetal condition until delivery is necessitated. It isestimated that around 200,000 children are born preterm in North Americadue to preeclampsia. Many of these babies will require costly intensivecare at birth and if they survive may face a lifetime of chronic illness(e.g. lung disease) or disability (e.g. cerebral palsy, mentalhandicaps, blindness). These conditions represent a significant impacton subsequent requirements for community health care resources.Therefore, reducing the incidence of preeclampsia and preterm birthwould have a tremendous positive impact on health care delivery.

SUMMARY OF THE INVENTION

The invention relates to methods and compositions for diagnosing andtreating conditions requiring regulation of trophoblast invasion.

The present inventors have studied the mechanisms that regulatetrophoblast invasion. The inventors have found that antisense disruptionof the expression of the TGFβ receptor, endoglin, triggers invasion ofcytotrophoblast from first trimester villous explants in vitroindicating that the TGFβ receptor system, and in particular endoglin,plays a critical role in regulating this process. Significantly, thepresent inventors defined components that endogenously regulatetrophoblast invasion. TGF-β₃ was found to be a major regulator oftrophoblast invasion in vitro. In particular, the presence of TGF-β₃ andits receptors at 5-8 weeks at a time when there is no spontaneoustrophoblast invasion and the absence of these molecules at 12-13 weekswhen spontaneous invasion occurs, establishes a major role for TGF-β₃ asan endogenous inhibitor of trophoblast invasion. Down-regulation ofTGF-β₃ (but not β₁ or β₂) expression using antisense oligonucleotides,stimulated extravillous trophoblast cell (EVT) outgrowth/migration andfibronectin production in 5-8 villous explants indicating that TGF-β₃acts to suppress in vivo trophoblast invasion. The effects of antisensetreatment to TGF-β₃ are specific as they are prevented by addition ofexogenous TGF-β₃ but not TGF-β₁ or TGF-β₂. The stimulatory effects ofTGF-β₃ are lost after 9 weeks of gestation which is compatible withTGF-β₃ being produced by the villi during a specific window of gestationwithin the first trimester (5-8 weeks) and that inhibition of itssynthesis stimulates trophoblast differentiation. Addition of exogenousTGF-β₃ to the villous explants inhibits fibronectin synthesis.

The clinical importance of TGF-β₃ in regulating trophoblast invasion hasbeen highlighted by the finding that TGF-β₃ is highly expressed introphoblast tissue of preeclamptic patients when compared to that inage-matched control placenta while there was no change in the expressionof either the β₁ or β₂ isoform. Fibronectin and α₅ integrin expressionwere also greater in preeclamptic placenta, indicating that inpreeclampsia, where there is shallow trophoblast invasion, trophoblastcells are arrested as an α₅ integrin phenotype producing TGF-β₃. Thesedata are supported by the finding that villous explants from a control(non-preeclamptic placenta, 32 weeks of gestation) spontaneously formedcolumns of trophoblasts that invaded the surrounding Matrigel, whileexplants from a preeclamptic placenta did not

In contrast to TGF-β₃, activin, a TGF-β receptor, has been found totrigger trophoblast invasion. Follistatin an activin binding proteininhibited the stimulatory effect of activin, and antibodies andantisense to endoglin.

Oxygen tension was also found to play a role in regulating trophoblastinvasion. The expression of the hypoxia inducible factor, HIF-1α,parallels that of TGF-β₃ in first trimester trophoblast (i.e. peaks at6-8 weeks but decreases after 9-10 weeks when oxygen tension increases).Expression of HIF-1α was dramatically increased in placentas ofpreeclamptic patients when compared to age-matched control tissue.Induction of HIF-1α by low PO₂ (around 6-8 weeks) up regulates TGF-β₃transcription and blocks trophoblast invasion. A failure of the systemto down-regulate at 9-11 weeks (either due to a block in response tonormoxia or the absence of an increase in oxygen tension) leads toshallow invasion and predisposes to preeclampsia.

In addition to endoglin, the present inventors have found that TGF-β₃signals through a receptor complex which includes RI (ALK1), RII andendoglin. While TGF-β RI (ALK-5) and TGF-β R-II are expressed throughoutthe villi and decidua at 9-10 weeks gestation, they were found to beabsent from the base of the proximal columns of the anchoring villi atthe transition zone between the villous and the invading EVT exactly atthe site where endoglin is up-regulated. This dramatic change in TGF-βreceptor expression indicates that EVT within the columns in situ arenot subject to the inhibitory actions of TGFβ, but via R-I and R-II theycome under the control of this ligand upon entering the decidua. Inaddition, antisense induced disruption of RI (ALK-1) and RII expressionstimulated trophoblast outgrowth/migration and fibronectin synthesis. Incontrast, antisense to RI (ALK-5) inhibited fibronectin synthesis.

Broadly stated the present invention relates to a method for detecting,preventing, and/or treating a condition requiring regulation oftrophoblast invasion by modulating (a) TGF-β₃ (b) receptors of cytokinesof the TGFβ family, (c) HIF-1α, and/or (d) O₂ tension. In accordancewith one aspect of the invention a method is provided for diagnosing ina subject a condition requiring regulation of trophoblast invasioncomprising detecting TGF-β₃, receptors of cytokines of the TGFβ family,or HIF-1α, in a sample from the subject. In an embodiment of thediagnostic method of the invention, a method is provided for diagnosingincreased risk of preeclampsia in a subject comprising detecting TGF-β₃or its receptors, or HIF-1α in a sample from the subject.

The invention also broadly contemplates a method for regulatingtrophoblast invasion comprising inhibiting or stimulating TGF-β₃,receptors of cytokines of the TGFβ family, HIF-1α, or O₂ tension. In anembodiment of the invention, a method is provided for increasingtrophoblast invasion in a subject comprising administering to thesubject an effective amount of an inhibitor of (a) TGF-β₃, (b) receptorsof cytokines of the TGFβ family, and/or (c) HIF-1α. In a preferredembodiment of the invention a method is provided for treating a womansuffering from, or who may be susceptible to preeclampsia comprisingadministering therapeutically effective dosages of an inhibitor of (a)TGF-β₃, (b) receptors of cytokines of the TGFβ family, and/or (c)HIF-1α. A therapeutically effective dosage is an amount of an inhibitorof (a), (b) and/or (c) effective to down regulate or inhibit TGF-β₃ inthe woman.

In another embodiment of the invention, a method is providing forreducing trophoblast invasion in a subject comprising administering aneffective amount of (a) TGF-β₃; (b) receptors of cytokines of the TGFβfamily; (c) HIF-1α; and/or (d) a stimulator of (a), (b) or (c). In apreferred embodiment, a method is provided for monitoring or treatingchoriocarcinoma or hydatiform mole in a subject comprising administeringtherapeutically effective dosages of (a) TGF-β₃; (b) receptors ofcytokines of the TGFβ family; (c) HIF-1α; and/or (d) a stimulator of(a), (b) or (c). An amount is administered which is effective to upregulate or stimulate TGF-β₃ in the subject.

The invention also relates to a composition adapted for regulatingtrophoblast invasion comprising a substance which inhibits or stimulatesTGF-β₃, receptors of cytokines of the TGFβ family, and/or HIF-1α, orregulates O₂ tension, in an amount effective to inhibit or stimulatetrophoblast invasion, and an appropriate carrier, diluent, or excipient.In an embodiment of the invention, a composition is provided fortreating a woman suffering from, or who may be susceptible topreeclampsia, comprising a therapeutically effective amount of aninhibitor of (a) TGF-β₃, (b) receptors of cytokines of the TGFβ family,and/or (c) HIF-1α, and a carrier, diluent, or excipient. In anotherembodiment of the invention, a composition is provided for monitoring ortreating choriocarcinoma or hydatiform mole in a subject comprising atherapeutically effective amount of (a) TGF-β₃; (b) receptors ofcytokines of the TGFβ family; (c) HIF-1α; and/or (d) a stimulator of(a), (b) or (c), and a carrier, diluent, or excipient.

The invention further relates to a method of selecting a substance thatregulates trophoblast invasion comprising assaying for a substance thatinhibits or stimulates TGF-β₃, receptors of a cytokine of the TGFβfamily, or HIF-1α. The substances may be used in the methods of theinvention to regulate trophoblast invasion.

The invention also relates to kits for carrying out the methods of theinvention.

Other objects, features and advantages of the present invention willbecome apparent from the following detailed description. It should beunderstood, however, that the detailed description and the specificexamples while indicating preferred embodiments of the invention aregiven by way of illustration only, since various changes andmodifications within the spirit and scope of the invention will becomeapparent to those skilled in the art from this detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described in relation to the drawings inwhich:

FIG. 1 shows the amino acid and nucleic acid sequence of TGF-β₃;

FIG. 2 shows the amino acid and nucleic acid sequence of HIF-1α;

FIG. 3A are Southern blots showing expression of TGF-β isoforms in humanplacenta in the first trimester of gestation;

FIG. 3B are photographs of immunoperoxidase staining of TGF-β₃ performedin placental sections at 5, 8, and 12 weeks of gestation;

FIG. 4A are photographs showing that addition of recombinant TGF-β₃ toantisense TGF-β₃ abolishes the antisense stimulatory effect ontrophoblast budding and outgrowth;

FIG. 4B are blots showing the reversal effect on antisense TGF-β₃stimulatory effect by exogenous TGF-β₃ for fibronectin synthesis;

FIG. 4C is a graph showing the changes in fibronectin estimated afternormalization to control cultures;

FIG. 4D are blots showing the effects on gelatinase activity inconditioned media of explants treated with sense or antisenseoligonucleotides to TGF-β₃;

FIG. 4E are blots showing that the antisense TGF-β₃ stimulatory effecton fibronectin production is lost after 9 weeks of gestation;

FIG. 5A are blots showing message expression of TGFβ isoforms, α₅integrin receptor, and fibronectin in preeclamptic and age-matchedcontrol placentae;

FIG. 5B are photographs of immunoperoxidase staining of TGF-β₃ performedin placental sections from normal pregnancies and pregnanciescomplicated by preeclampsia;

FIG. 6A are photographs showing that antisense oligonucleotides toTGF-β₃ induces the formation of trophoblast cells in preeclampticvillous explants;

FIG. 6B shows the results of gelatin Zymography of explants of 32 weeksgestation from preeclamptic placentae treated with antisense or controlsense oligonucleotides to TGF-β₃ for 5 days;

FIG. 6C are Western blots with MMP9 antisera of explants of 32 weeksgestation from preeclamptic placentae treated with antisense or controlsense oligonucleotides to TGF-β₃ for 5 days;

FIG. 7A is a blot showing expression of HIF-1α placenta in the firsttrimester of gestation;

FIG. 7B is a blot showing expression of HIF-1α in preeclamptic (PE) andage-matched control placenta (C);

FIG. 8 is a blot showing the effect of low oxygen tension on TGF-β₃ andHIF-1α expression in villous explants;

FIG. 9 are photographs at 20% O₂ and 3% O₂ (25× and 50×) showing theeffect of low oxygen tension on villous explant morphology; and

FIG. 10 are photographs showing the effect of antisense to HIF-1α onvillous explant morphology.

DETAILED DESCRIPTION OF THE INVENTION 1. Diagnostic Methods

As hereinbefore mentioned, the present invention provides a method fordiagnosing in a subject a condition requiring regulation of trophoblastinvasion comprising detecting TGF-β₃, receptors of cytokines of the TGFβfamily, or HIF-1α in a sample from the subject. In an embodiment of thediagnostic method of the invention, a method is provided for diagnosingincreased risk of preeclampsia in a subject comprising detecting TGF-β₃,its receptors, or HIF-1α in a sample from the subject.

TGF-β₃ is a cytokine of the TGFβ family and it has the structuralcharacteristics of the members of the TGFβ family. TGFβ is produced as aprecursor characterised by having an N-terminal hydrophobic signalsequence for translocation across the endoplasmic reticulum, apro-region, and a C-terminal bioactive domain. Prior to release from thecell, the pro-region is cleaved at a site containing four basic aminoacids immediately preceding the bioactive domain (Massague, 1990, Annu.Review. Cell Biol. 6:597).

The precursor structure of TGFβ is shared by members of the TGFβ family,with the exception of the TGFβ4 precursor which lacks a distinguishablesignal sequence. The degree of identity between family members in theC-terminal bioactive domain is from 25 to 90% (See Basler et al. Cell,73:687, 1993, FIG. 2). All nine cysteines are conserved in the bioactivedomain in the TGFβ family. The bioactive domain is cleaved to generate amature monomer.

The TGFβ family includes five members, termed TGFβ1 through TGFβ5, allof which form homodimers of about 25 kd (reviewed in Massague, 1990).The family also includes TGFβ1.2 which is a heterodimer containing a β31and a β2 subunit linked by disulfide bonds. The five TGFβ genes arehighly conserved. The mature TGFβ processed cytokines produced from themembers of the gene family show almost 100% amino acid identity betweenspecies and the five peptides as a group show about 60-80% identity. Theamino acid sequence and nucleic acid sequence of TGF-β₃ are shown inFIG. 1 (See also sequences for GenBank Accession Nos. HSTGF31-HSTGF37and HSTGFβ3M).

“Receptors of cytokines of the TGFβ family” or “TGFβ receptors” refersto the specific cell surface receptors which bind to cytokines of theTGFβ family, in particular TGF-β₃, including the TGF-β type I receptor(ALK-1 or ALK-5)) (R-I), TGF-β type II receptor (R-II), betaglycan,endoglin and activin, and complexes of the receptors, in particular aRI-RII-endoglin complex. Endoglin binds TGFβ₁ and β₃ with high affinity(K_(D)=50 pM). Betaglycan has considerable sequence homology to endoglin(Chiefetz, S., et al J. Biol. Chem. 267: 19027, 1992; Lopez-Casillas,F., et al, Cell 67:785, 1991; Wang, X. F., et al, Cell 67:797, 1991), itcan bind all three forms of TGF-β₃, and it regulates access of theligands to R-I and R-II which are serine/threonine kinases and unlikebetaglycan, are necessary for signal transduction (Wrana, J. L. et al,Cell 71:1003, 1992, Lopez-Casillas et al, Cell 73:1435, 1993; Franzen,P., et al Cell 75:681, 1993; Laiho, M. et al, J. Biol. Chem. 266:9108;Massague, J. et al, Trends Cell Biol. 4:172, 1994). TGFβ R-II is anintegral membrane protein which contains a short extracellular domain, asingle transmembrane domain, and an intracellular serine/threoninekinase domain (Lin H. Y. et al., Cell 68:775, 1992). Serine/threoninekinases encoding type II receptors have been cloned which arestructurally related to the type II receptors (Wrana, J. L. et al, Cell71:1003, 1992, ten Dikje, P., et al, Oncogene 8:2879, 1993; Ebner, R.,et al Science 260:1344, 1993; Ebner, R., et al Science 262:900, 1993).TGFβ R-I (human ALK-5), binds TGFβ₁ and β₃ only in the presence of TGFβR-II (Wrana, J. L. et al, Cell 71:1003, 1992). The human ALK-1 (TGFβR-I) binds TGFβ when forming a heterodimeric complex with TGFβ R-II(Franzen, P., et al Cell 75:681, 1993). TGFβ R-II kinase, which isendogenously phosphorylated, phosphorylates and activates R-I which theninitiates further downstream signals (Wrana, J. L. et al, Nature370:341, 1994).

Hypoxia-inducible factor-I (HIF-1) is present in nuclear extracts ofmany mammalian cells cultivated in a low oxygen atmosphere (Semenza, G.L. et al Mol. Cell. Biol. 12:5447, 1992; Wang, G. L. et al J. Biol.Chem. 268:21513, 1993). HIF-I binds as a phosphoprotein to a short DNAmotif (BACGTSSK) identified in the 3′-flanking regions of manyhypoxia-induced genes (Semenza, G. L. et al. J. Biol Chem 269:23757,1994; Liu, Y., et al Circulation Res. 77:638, 1995; Firth, J. D. et alProc. Natl. Acad, Sci. USA 91:6496, 1994; Abe, M., et al, Anal. Biochem.216:276, 1994). HIF-I binds DNA as a heterodimeric complex composed oftwo subunits of the inducible HIF-1α and the constitutively expressedHIF-Iβ.

TGF-β₃, receptors of cytokines of the TGFβ family (e.g., TGFβ RI(ALK-1), TGFβ RII, or a complex of RI-RII-endoglin), or HIF-1α may bedetected in a variety of samples from a patient. Examples of suitablesamples include cells (e.g. fetal or maternal); and, fluids (fetal ormaternal), including for example, serum, plasma, amniotic fluid, saliva,and conditioned medium from fetal or maternal cells.

TGF-β₃, receptors of cytokines of the TGFβ family, or HIF-1α may bedetected using a substance which directly or indirectly interacts withthe cytokine, TGFβ receptors, or HIF-1α. For example, antibodiesspecific for TGF-β₃, the TGFβ receptors, or HIF-1α may be used todiagnose and monitor a condition requiring regulation of trophoblastinvasion. A method of the invention using antibodies may utilizeCountercurrent Immuno-Electrophoresis (CIEP), Radioimmunoassays,Radioimmunoprecipitations, and Enzyme-Linked Immuno-Sorbent Assays(ELISA), Dot Blot assays, Inhibition or Competition assays and sandwichassays (see U.S. Pat. Nos. 4,376,110 and 4,486,530; see also Antibodies:A Laboratory Manual, supra).

Antibodies used in the methods of the invention include monoclonalantibodies, polyclonal antibodies, antibody fragments (e.g., Fab, andF(ab′)₂ and recombinantly produced binding partners. Polyclonalantibodies may be readily generated by one of ordinary skill in the artfrom a variety of warm-blooded animals such as horses, cows, variousfowl, rabbits, mice, or rats. Monoclonal antibodies may also be readilygenerated using conventional techniques (see U.S. Pat. Nos. RE 32,011,4,902,614, 4,543,439, and 4,411,993 which are incorporated herein byreference; see also Monoclonal Antibodies, Hybridomas: A New Dimensionin Biological Analyses, Plenum Press, Kennett, McKearn, and Bechtol(eds.), 1980, and Antibodies: A Laboratory Manual, Harlow and Lane(eds.), Cold Spring Harbor Laboratory Press, 1988, which are alsoincorporated herein by reference). Binding partners may be constructedutilizing recombinant DNA techniques to incorporate the variable regionsof a gene which encodes a specifically binding antibody (See Bird etal., Science 242:423-426, 1988).

Antibodies may also be obtained from commercial sources. For example,antibodies to TGF-β₃ may be obtained from American Diagnostics Inc., CT.USA, Oncogene Science, NY, USA, and Dimension Laboratories, Mississauga,Canada.

The presence of TGF-β₃ in a sample may also be determined by measuringthe binding of the cytokine to compounds which are known to interactwith TGF-β₃ such as its receptors, or decorin, thrombospondin, the serumglycoprotein α2-macroglobulin, fetuin, or thyroglobulin (Y. Yamaguchi,D. M. Mann, E. Ruoslahti, Nature 346, 281 (1990); S. Scholtz-Chemy J. E.Murphy-Ullrich, J. Cell Biol. 122, 923 (1993); O'Conner-McCourt, L, M.Wakefield J. Biol. Chem. 262, 14090 (1987); and J. Massague Curr. Biol.1, 117 (1991)). These compounds are referred to herein as “TGFβ BindingCompounds”.

The presence of receptors of cytokines of the TGFβ family may bedetermined by measuring the binding of the receptors to molecules (orparts thereof) which are known to interact with the receptors such astheir ligands. In particular, peptides derived from sites on ligandswhich bind to the receptors may be used. A peptide derived from aspecific site on a ligand may encompass the amino acid sequence of anaturally occurring binding site, any portion of that binding site, orother molecular entity that functions to bind an associated molecule. Apeptide derived from such a site will interact directly or indirectlywith an associated receptor molecule in such a way as to mimic thenative binding site. Such peptides may include competitive inhibitors,enhancers, peptide mimetics, and the like as discussed below.

The presence of HIF-1α may be determined by measuring the binding ofHIF-α1 to DNA molecules which are known to interact with HIF-α1 such ashypoxia inducing genes. The TGFβ binding compounds and molecules thatinteract with the receptors and HIF-1α are referred to herein as“Binding Compounds”.

The antibodies specific for the TGF-β₃, TGFβ receptors, or HIF-1α, orthe Binding Compounds may be labelled using conventional methods withvarious enzymes, fluorescent materials, luminescent materials andradioactive materials. Examples of suitable enzymes include horseradishperoxidase, alkaline phosphatase, β-galactosidase, oracetylcholinesterase; examples of suitable fluorescent materials includeumbelliferone, fluorescein, fluorescein isothiocyanate, rhodamine,dichlorotriazinylamine fluorescein, dansyl chloride or phycoerythrin; anexample of a luminescent material includes luminol; and examples ofsuitable radioactive materials include radioactive phosphorous ³²P,iodine I¹²⁵, I¹³¹ or tritium.

An antibody to TGF-β₃, a TGFβ family receptor, or HIF-1α, or a BindingCompound may also be indirectly labelled with a ligand binding partner.For example, the antibodies, or a TGF-β₃ Binding Compound may beconjugated to one partner of a ligand binding pair, and the TGF-β₃ maybe coupled to the other partner of the ligand binding pair.Representative examples include avidin-biotin, and riboflavin-riboflavinbinding protein. Preferably the antibodies are biotinylated. Methods forconjugating the antibodies discussed above with the ligand bindingpartner may be readily accomplished by one of ordinary skill in the art(see Wilchek and Bayer, “The Avidin-Biotin Complex in BioanalyticalApplications,” Anal Biochem. 171:1-32, 1988).

The antibodies or Binding Compounds used in the method of the inventionmay be insolubilized. For example, the antibodies or Binding Compoundsmay be bound to a suitable carrier. Examples of suitable carriers areagarose, cellulose, dextran, Sephadex, Sepharose, carboxymethylcellulose polystyrene, filter paper, ion-exchange resin, plastic film,plastic tube, glass beads, polyamine-methyl vinyl-ether-maleic acidcopolymer, amino acid copolymer, ethylene-maleic acid copolymer, nylon,silk, etc. The carrier may be in the shape of, for example, a tube, testplate, beads, disc, sphere etc. The insolubilized compound or antibodiesmay be prepared by reacting the material with a suitable insolublecarrier using known chemical or physical methods, for example, cyanogenbromide coupling.

Indirect methods may also be employed in which a primaryantigen-antibody reaction is amplified by the introduction of a secondantibody, having specificity for the antibody reactive against thecytokine. By way of example, if the antibody having specificity againstTGF-β₃ is a rabbit IgG antibody, the second antibody may be goatanti-rabbit gamma-globulin labelled with a detectable substance asdescribed herein.

TGF-β₃, TGFβ receptors, or HIF-1α can also be assayed in a sample usingnucleotide probes to detect nucleic acid molecules encoding a TGF-β₃,the TGFβ receptors, or HIF-1α. Suitable probes include nucleic acidmolecules based on nucleic acid sequences encoding TGF-β₃, the TGFβreceptors, or HIF-1α. A nucleotide probe may be labelled with adetectable substance such as a radioactive label which provides for anadequate signal and has sufficient half-life such as ³²P, ³H, ¹⁴C or thelike. Other detectable substances which may be used include antigensthat are recognized by a specific labelled antibody, fluorescentcompounds, enzymes, antibodies specific for a labelled antigen, andluminescent compounds. An appropriate label may be selected havingregard to the rate of hybridization and binding of the probe to thenucleotide to be detected and the amount of nucleotide available forhybridization Labelled probes may be hybridized to nucleic acids onsolid supports such as nitrocellulose filters or nylon membranes asgenerally described in Sambrook et al, 1989, Molecular Cloning, ALaboratory Manual (2nd ed.).

A nucleic acid molecule encoding TGF-β₃, TGFβ receptors, or HIF1α canalso be detected by selective amplification of the nucleic acidmolecules using polymerase chain reaction (PCR) methods. Syntheticoligonucleotide primers can be constructed from the sequences of theTGF-β₃, TGFβ receptors, or HIF1α using conventional methods. A nucleicacid can be amplified in a sample using these oligonucleotide primersand standard PCR amplification techniques.

In a preferred embodiment of the invention, a method is provided fordiagnosing increased risk of preeclampsia in a subject comprisingdetecting TGF-β₃, TGFβ R-I (ALK-1), TGFβ R-II, endoglin, HIF-1α, or acomplex of R-I (ALK-1)-R-II-endoglin in a sample, and in particularusing antibodies specific for TGF-β₃. Levels of TGF-β₃, TGFβ receptorsor complexes thereof, or HIF-1α may be measured during the firsttrimester of pregnancy (approximately 1 to 14 weeks). It is preferredthat at least two measurements be taken during this period, preferablyincluding a measurement at about 14 to 16 weeks. If the levels aresignificantly increased as compared to levels typical for women who donot suffer from preeclampsia, the patient is diagnosed as having anincreased risk of suffering preeclampsia. Levels above those typical forwomen who do not suffer from preeclampsia may be suspect and furthermonitoring and measurement of TGF-β₃, TGFβ receptors, or HIF-1α may beappropriate. The information from the diagnostic method may be used toidentify subjects who may benefit from a course of treatment, such astreatment via administration of inhibitors of TGF-β₃ as discussedherein.

It will also be appreciated that the above methods may also be useful inthe diagnosis or monitoring of choriocarcinoma or hydatiform mole whichinvolves uncontrolled trophoblast invasion (i.e. may be associated withabnormally low levels of TGF-β₃, TGFβ family receptors, or HIF1α).Further the above methods may be used to diagnose or monitor otherpregnancy complications including intrauterine growth restriction, molarpregnancy, preterm labour, preterm birth, fetal anomalies, and placentalabruption. The diagnostic and monitoring methods of the invention mayalso involve determining responsiveness of cells to oxygen.

The invention also relates to kits for carrying out the methods of theinvention. The kits comprise instructions, negative and positivecontrols, and means for direct or indirect measurement of TGF-β₃, TGFβreceptors, or HIF1α.

2. Regulation of Trophoblast Invasion in a Subject

The invention also provides a method of regulating trophoblast invasioncomprising directly or indirectly inhibiting or stimulating (a) TGF-β₃(b) receptors of cytokines of the TGFβ family, (c) HIF1α; and/or (d) O₂tension, preferably inhibiting or stimulating TGF-β₃. Trophoblastinvasion may also be regulated by optimizing oxygenation of tissues.

In an embodiment of the invention, a method is provided for increasingtrophoblast invasion in a subject comprising administering an effectiveamount of a substance which is an inhibitor of (a) TGF-β₃, (b) receptorsof cytokines of the TGFβ family, and/or (c) HIF-1α. In particular,methods are provided for treating a women suffering from or who may besusceptible to preeclampsia.

In another embodiment of the invention, a method is providing forreducing trophoblast invasion in a subject comprising administering aneffective amount of (a) TGF-β₃; (b) receptors of cytokines of the TGFβfamily; (c) HIF-α1; and/or (d) a stimulator of (a), (b) or (c). Themethod may be used to monitor or treat choriocarcinoma or hydatiformmole.

The methods of the invention may also be used to monitor or treat othercomplications of pregnancy such as intrauterine growth restriction,molar pregnancy, preterm labour, preterm birth, fetal anomalies, orplacental abruption.

Substances that regulate trophoblast invasion can be selected byassaying for a substance that inhibits or stimulates the activity ofTGF-β₃, TGFβ receptors, or HIF-1α. A substance that regulatestrophoblast invasion can also be identified based on its ability tospecifically interfere or stimulate the interaction of (a) TGF-β₃ and areceptor for the cytokine (e.g. the interaction of TGF-β₃ and endoglin,or TGF-β₃ and R-I, R-II, or a complex of R-I-R-II endoglin, or (b)TGF-β₃ and HIF1α.

Therefore, a method is provided for evaluating a compound for itsability to regulate trophoblast invasion comprising the steps of:

(a) reacting TGF-β₃ or a part thereof that binds to a receptor of acytokine of the TGFβ family, with a receptor of a cytokine of the TGFβfamily or a part thereof that binds to TGF-β₃, and a test substance,wherein the TGF-β₃ and receptor of a cytokine of the TGFβ family orparts thereof, are selected so that they bind to form a ligand-receptorcomplex; and

(b) comparing to a control in the absence of the substance to determinethe effect of the substance.

In particular, a method is provided for identifying a substance whichregulates trophoblast invasion comprising the steps of:

(a) reacting TGF-β₃ or a part thereof that binds to a receptor of acytokine of the TGFβ family, and a receptor of a cytokine of the TGFβfamily or a part thereof that binds to TGF-β₃, and a test substance,wherein the TGF-β₃ and receptor of a cytokine of the TGFβ family orparts thereof, are selected so that they bind to form a ligand-receptorcomplex, under conditions which permit the formation of ligand-receptorcomplexes, and

(b) assaying for complexes, for free substance, for non-complexed TGF-β₃or receptor, or for activation of the receptor.

The substance may stimulate or inhibit the interaction of TGFβ or a partthereof that binds the TGFβ receptor, and the TGFβ receptor.

In an embodiment of the invention a receptor complex is employedcomprising TGFβ R-I (ALK-1)-TGFβ RII-endoglin.

Activation of the receptor may be assayed by measuring phosphorylationof the receptor, or by assaying for a biological affect on a cell, suchmeasuring biochemical markers of trophoblast invasion such as cellproliferation, FN synthesis, integrin expression, up regulation ofgelatinase and type IV collagenase expression and activity.

The invention also provides a method for evaluating a substance for itsability to regulate trophoblast invasion comprising the steps of:

(a) reacting TGF-β₃ or a part of TGF-β₃ that binds to HIF-1α, HIF-1α ora part of the protein that binds to TGF-β₃, and a test substance,wherein the TGF-β₃ or part thereof, and HIF-1α or part thereof bind toform a TGF-β3-HIF-1α complex; and

(b) comparing to a control in the absence of the substance to determinethe effect of the substance.

The substance may stimulate or inhibit the interaction of TGF-β₃ andHIF-1α, or the activation of TGFβ by HIF-1α and thereby regulatetrophoblast invasion.

The substances identified using the methods of the invention include butare not limited to peptides such as soluble peptides including Ig-tailedfusion peptides, members of random peptide libraries and combinatorialchemistry-derived molecular libraries made of D- and/or L-configurationamino acids, phosphopeptides (including members of random or partiallydegenerate, directed phosphopeptide libraries), antibodies [e.g.polyclonal, monoclonal, humanized, anti-idiotypic, chimeric, singlechain antibodies, fragments, (e.g. Fab, F(ab)₂, and Fab expressionlibrary fragments, and epitope-binding fragments thereof)], and smallorganic or inorganic molecules. The substance may be an endogenousphysiological compound or it may be a natural or synthetic compound. Thesubstance may be a TGFβ R-I-TGFβ R-II-endoglin complex, whichcompetitively inhibits the binding of TGF-β₃ to its natural receptors.The invention contemplates isolated TGFβ R-I-TGFβ R-II-endoglincomplexes and their use in regulating trophoblast invasion.

The substances may be peptides derived from the binding sites of TGF-β₃and a receptor for the cytokine such as endoglin, R-I or R-II, or acomplex of R-I-R-II-endoglin; or the binding sites of TGF-β₃ and HIF1α.A peptide derived from a specific binding site may encompass the aminoacid sequence of a naturally occurring binding site, any portion of thatbinding site, or other molecular entity that functions to bind anassociated molecule. A peptide derived from such a binding site willinteract directly or indirectly with an associated molecule in such away as to mimic the native binding domain. Such peptides may includecompetitive inhibitors, enhancers, peptide mimetics, and the like. Allof these peptides as well as molecules substantially homologous,complementary or otherwise functionally or structurally equivalent tothese peptides may be used for purposes of the present invention.

“Peptide mimetics” are structures which serve as substitutes forpeptides in interactions between molecules (See Morgan et al (1989),Ann. Reports Med. Chem. 24:243-252 for a review). Peptide mimeticsinclude synthetic structures which may or may not contain amino acidsand/or peptide bonds but retain the structural and functional featuresof a peptide, or enhancer or inhibitor of the invention. Peptidemimetics also include peptoids, oligopeptoids (Simon et al (1972) Proc.Natl. Acad, Sci USA 89:9367); and peptide libraries containing peptidesof a designed length representing all possible sequences of amino acidscorresponding to a peptide of the invention.

Peptides may be synthesized by conventional techniques. For example, thepeptides may be synthesized by chemical synthesis using solid phasepeptide synthesis. These methods employ either solid or solution phasesynthesis methods (see for example, J. M. Stewart, and J. D. Young,Solid Phase Peptide Synthesis, 2^(nd) Ed., Pierce Chemical Co., RockfordIll. (1984) and G. Barany and R. B. Merrifield, The Peptides: AnalysisSynthesis, Biology editors E. Gross and J. Meienhofer Vol. 2 AcademicPress, New York, 1980, pp. 3-254 for solid phase synthesis techniques;and M Bodansky, Principles of Peptide Synthesis, Springer-Verlag, Berlin1984, and E. Gross and J. Meienhofer, Eds., The Peptides: Analysis,Synthesis, Biology, supra, Vol 1, for classical solution synthesis.)

Peptide mimetics may be designed based on information obtained bysystematic replacement of L-amino acids by D-amino acids, replacement ofside chains with groups having different electronic properties, and bysystematic replacement of peptide bonds with amide bond replacements.Local conformational constraints can also be introduced to determineconformational requirements for activity of a candidate peptide mimetic.The mimetics may include isosteric amide bonds, or D-amino acids tostabilize or promote reverse turn conformations and to help stabilizethe molecule. Cyclic amino acid analogues may be used to constrain aminoacid residues to particular conformational states. The mimetics can alsoinclude mimics of inhibitor peptide secondary structures. Thesestructures can model the 3-dimensional orientation of amino acidresidues into the known secondary conformations of proteins. Peptoidsmay also be used which are oligomers of N-substituted amino acids andcan be used as motifs for the generation of chemically diverse librariesof novel molecules.

A substance that regulates trophoblast invasion may be a molecule whichinterferes with the transcription and/or translation of TGF-β₃, TGFβreceptors, or HIF-1α. For example, the sequence of a nucleic acidmolecule encoding TGF-β₃, TGFβ receptors (e.g. endoglin, R-I (ALK-1),R-II, or RI-RIII-endoglin complex), or fragments thereof, may beinverted relative to its normal presentation for transcription toproduce an antisense nucleic acid molecule. An antisense nucleic acidmolecule may be constructed using chemical synthesis and enzymaticligation reactions using procedures known in the art. Examples ofantisense molecules for TGF-β₃ are 5′-CCTTTGCAAGTGCATC-3′ (SEQ ID NO: 1)and 5′-GATGCACTTGCAAAGG-3′ (SEQ ID NO: 2).

The treatment methods and compositions described herein may usesubstances that are known inhibitors of TGF-β₃. For example, antibodiesto TGF-β₃, the TGFβ Binding Compounds including decorin,α2-macroglobulin, fetuin, and thyroglobulin, or peptides derived fromthe sites on these compounds that bind to TGF-β₃, or chimeras of thesemolecules may be employed.

Activin, another member of the TGFβ receptor family, triggerstrophoblast invasion and therefore it may be used to enhance trophoblastinvasion in a subject.

The utility of a selected inhibitor or stimulator may be confirmed inexperimental model systems. For example, the human villous explantculture system described by Genbacev et al. (21) can be used to confirmthe utility of an inhibitor for treatment of preeclampsia.

In a preferred embodiment of the invention a method is provided fortreating a woman suffering from, or who may be susceptible topreeclampsia comprising administering therapeutically effective dosagesof an inhibitor of TGF-β₃ or TGFβ receptors, an inhibitor of HIF-1α, ora substance identified in accordance with the methods of the invention.Preferably treatment with the inhibitor begins early in the firsttrimester, at about 10 to about 16 weeks, and may continue untilmeasured TGF-β₃ levels, TGF-β receptor levels, or HIF-1α levels arewithin the normal range. Preferably, treatment with the inhibitor orsubstance is not continued beyond about 30 weeks of gestation. For thepurposes of the present invention normal TGF-β₃ levels, TGFβ receptorlevels, or HIF-1α levels are defined as those levels typical forpregnant women who do not suffer from preeclampsia. Treatment with theinhibitor is discontinued after TGF-β₃ levels, TGF-β receptor levels,and/or HIF-1α levels are within normal range, and before any adverseeffects of administration of the inhibitor are observed.

One or more inhibitors or one or more stimulators of TGF-β₃, TGFβreceptors, or HIF-1α, or substances selected in accordance with themethods of the invention including Binding Compounds, may beincorporated into a composition adapted for regulating trophoblastinvasion. In an embodiment of the invention, a composition is providedfor treating a woman suffering from, or who may be susceptible topreeclampsia, comprising a therapeutically effective amount of aninhibitor of TGF-β₃, TGFβ receptors, or HIF-1α, or substance selected inaccordance with the methods of the invention including TGFβ BindingCompounds, and a carrier, diluent, or excipient.

The compositions of the invention contain at least one inhibitor orstimulator of TGF-β₃, TGFβ receptors, or HIF-1α, or substance identifiedin accordance with the methods of the invention, alone or together withother active substances. Such compositions can be for oral, parenteral,or local use. They are therefore in solid or semisolid form, for examplepills, tablets, and capsules.

The composition of the invention can be intended for administration tosubjects such as humans or animals. The pharmaceutical compositions canbe prepared by per se known methods for the preparation ofpharmaceutically acceptable compositions which can be administered topatients, and such that an effective quantity of the active substance iscombined in a mixture with a pharmaceutically acceptable vehicle,carrier or diluent. Suitable vehicles are described, for example, inRemington's Pharmaceutical Sciences (Remington's PharmaceuticalSciences, Mack Publishing Company, Easton, Pa., USA 1985).

The compositions of the invention may be administered together with orprior to administration of other biological factors that have been foundto affect trophoblast proliferation. Examples of these factors includeIL-11 (Ireland et al Blood 84:267a, 1994), G-CSF, GM-CSF and M-CSF (U.S.Pat. No. 5,580,554 to Keith).

The compositions and other biological factors may be administeredthrough any known means. Systemic administration, such as intravenous orsubcutaneous administration is preferred. A therapeutically effectiveamount of an active ingredient e.g. inhibitor is an amount effective toelicit the desired therapeutic response but insufficient to cause atoxic reaction. The dosage for the compositions is determined by theattending physician taking into account factors such as the condition,body weight, diet of the subject, and the time of administration.

For example, a therapeutically effective dose of an inhibitor, e.g. anamount sufficient to lower levels of TGF-β₃ to normal levels, is about 1to 200 μg/kg/day. The method of the invention may involve a series ofadministrations of the composition. Such a series may take place over aperiod of 7 to about 21 days and one or more series may be administered.The composition may be administered initially at the low end of thedosage range and the dose will be increased incrementally over apreselected time course.

An inhibitor or stimulator of TGF-β₃, receptors of cytokines of the TGFβfamily, or HIF-1α, or substance identified in accordance with themethods of the invention may be administered by gene therapy techniquesusing genetically modified trophoblasts or by directly introducing genesencoding the inhibitors or stimulators of TGF-β₃, or receptors ofcytokines of the TGFβ family, or substances into trophoblasts in vivo.Trophoblasts may be transformed or transfected with a recombinant vector(e.g. retroviral vectors, adenoviral vectors and DNA virus vectors).Genes encoding inhibitors or stimulators, or substances may beintroduced into cells of a subject in vivo using physical techniquessuch as microinjection and electroporation or chemical methods such ascoprecipitation and incorporation of DNA into liposomes. Antisensemolecules may also be introduced in vivo using these conventionalmethods.

The following non-limiting examples are illustrative of the presentinvention:

Example 1 Materials and Methods Establishment of Human TrophoblastVillous Explant Culture

Villous explant cultures were established from first trimester humanplacentae by a modification of the method of Genbacev et al. (21). Firsttrimester human placentae (5-8 weeks gestation) were obtained fromelective terminations of pregnancies by dilatation and curettage.Placental tissue was placed in ice-cold phosphate buffered saline (PBS)and processed within two hours of collection. The tissue was washed insterile PBS, and aseptically dissected using a microscope to removeendometrial tissue and fetal membranes. Small fragments of placentalvilli (15-20 mg wet weight) were teased apart and placed on atransparent Biopore™ membrane of 12-mm diameter Millicell®-CM culturedish inserts with a pore size of 0.4 μm (Millipore Corp, Bedford,Mass.). The inserts were precoated with 0.2 ml of undiluted Matrigel®reagent (Collaborative Research Inc), polymerized at 37° C. for 30 min,and transferred in a 24-well culture dish. Explants were cultured inDMEM/F12 (Gibco, Grand Island, N.Y.) supplemented with 100 μg/mlstreptomycin, 100 U/ml penicillin and 0.25 μg/ml ascorbic acid, pH 7.4.Culture media were changed every 48 h and collected for measurement ofhuman chorionic gonadotropin (hCG) and progesterone. Villous explantswere kept in culture for up to 6 days. Flattening of the distal end ofthe villous tips, their adherence to Matrigel® reagent and theappearance of extravillous trophoblast cells (EVT) breaking through fromthe tips, were used as markers of morphological integrity andtrophoblast differentiation as previously described by Genbacev et al.(21). EVT cell outgrowth and migration were consistently monitored andquantitated using the ratio of EVT outgrowths/villous tip, where thenominator, EVT outgrowths, represents the number of extravilloustrophoblast columns sprouting from the villous tips plus the number ofislands of EVT invading into the Matrigel. The denominator representsthe total number of villous tips in a single explant culture. EVToutgrowth from the distal end of the villous tips and their migrationinto the surrounding matrix were observed for up to 6 days in culture.

Initial experiments, in the presence of 10% (v/v) fetal bovine serum(FBS), demonstrated that DMEM/F12 supported greater EVT sprouting andmigration than DMEM. In order to study the effect of various agents onEVT differentiation, a serum-free villous explant culture system wasdeveloped. Villous explants of 5-8 weeks gestation were incubatedovernight in DMEM/F12 or DMEM/F12+10% (v/v) FBS to promote attachment ofthe distal villous tips to the Matrigel® reagent. Following thisincubation period, explants were washed with fresh medium and culturedin either serum-free DMEM/F12 or DMEM/F12 supplemented with varyingconcentrations of FBS (0.5% and 10%). In serum-free medium EVT/villoustip was 1.58±0.08 while it was 1.32±0.17 in 0.5% FBS and 1.26±0.02 in10% FBS (mean±s.e.m. of 3 separate experiments, each carried out intriplicate), suggesting that villous explant cultures were viable for atleast 6 days in a serum-free medium. All subsequent experiments wereperformed with DMEM/F12 in the absence of serum.

The viability of the explant cultures was assessed by measuring hCG andprogesterone production rate in the culture media collected at the timeof media change every 48 h. Both hCG and progesterone concentrationswere measured by radioimmunoassays (Coat-A-Count® HCG IRMA kit andprogesterone; DPC, Los Angeles, Calif.). Results are expressed forprogesterone as ng/0.1 g wet weight tissue and for hCG as IU/0.1 g wetweight tissue.

Antibodies

Murine monoclonal antibody (MAb) 44G4 specific for human endoglin wasproduced as previously described (22). IgG purified from ascites wasused in all functional assays. Rat MAb 7D3 against cytokeratin was agift from Drs. S. Fisher and C. Damsky (San Francisco, Calif., USA).Murine MAb TS2/7 against the α₁ integrin subunit was provided by Dr. M.Hemler (Boston, Mass., USA). Mouse MAb P1D6 against the α₅ integrinsubunit was from Chemicon (Temecula, Calif.); rat MAb GoH3 against theα₆ integrin subunit was purchased from Serotec Canada (Toronto, Ont.Canada) and the neutralizing rabbit polyclonal antibody to TGF-β wasfrom R&D (Minneapolis, Minn.). Purified mouse IgG from Coulter (Hialeah,Fla.) and rat IgG from Sigma (Diagnostic, Toronto, Ont. Canada) wereused as negative controls.

Immunohistochemistry

Villous explants kept in culture for 6 days in the presence or absenceof antisense oligonucleotides to endoglin were dissected away from theinsert membrane with the supporting Matrigel. Explants and placentaltissue of 9 weeks gestation were fixed for 1 h at 4° C. in 4% (vol/vol)paraformaldehyde, cryoprotected by incubation in 10% (vol/vol) glycerolfor 30 min and 50% (vol/vol) OCT compound (Tissue Tek, Miles, Ind.) for18 h, embedded in 100% OCT and frozen in liquid nitrogen. Ten micronsections were cut with a cryostat and mounted on poly-L-lysine coatedslides. To verify the quality of the tissue and select the mostrepresentative sections, every tenth one was stained with haematoxylinand eosin; neighboring sections were selected and stained using theavidin-biotin immunoperoxidase method. Endogenous peroxidase enzymeactivity was quenched with 3% (vol/vol) hydrogen peroxide in 0.01 MTris-HCl, pH 7.4, containing 0.15 M NaCl, or methanol for 10 minutes.Non-specific binding sites were blocked using 5% (vol/vol) normal horseserum (NHS) and 1% (wt/vol) BSA in Tris-buffer for 40 min at 23° C. Inthe case of murine monoclonal antibodies, a higher background wasobserved and it was necessary to preincubate the sections with 5%(wt/vol) Texas Red®-conjugated goat anti-mouse IgG antibody for 1 h at23° C. prior to incubation with primary antibody at 4° C. for 1 h.Optimal antibody concentrations were established in preliminaryexperiments by titration and were used as follows: 44G4, 5 μg/ml; rabbitanti-TGF-13, 20 μg/ml; P1D6, 20 μg/ml; GoH3, 0.5 μg/ml; TS2/7, 20 μg/m1;7D3, 10 μg/ml. The slides were washed three times with Tris-buffer, thenincubated with a 200-fold dilution of biotinylated goat anti-rabbit IgGor a 300-fold dilution of biotinylated horse anti-mouse or anti-rat IgG,for 1 h at 4° C. After washing three times with Tris-buffer, the slideswere incubated with an avidin-biotin complex for 1 h. Slides were washedagain in Tris-buffer and developed in 0.075% (wt/vol)3,3-diaminobenzidine in Tris-buffer, pH 7.6, containing 0.002% (vol/vol)H₂O₂ giving rise to a brown product. After light counterstaining withtoluidine blue, slides were dehydrated in an ascending ethanol series,cleared in xylene, and mounted. In control experiments, primaryantibodies were replaced with non-immune mouse or rat IgG, or blockingsolution [5% (vol/vol) NGS and 1% (wt/vol) BSA].

Effect of Antibody to Endoglin on EVT Formation

Villous explants, prepared from placentae of 5-8 weeks gestation, wereincubated for 16 h in DMEM/F12. Explant cultures were then washed withfresh serum-free medium and incubated in serum-free DMEM/F12 mediumcontaining increasing concentrations of MAb 44G4 IgG (0.1 to 10 μg/ml).DMEM/F12 medium±antibody was replaced every 48 h. Antibody addition wasthus performed on day 1, 3 and 5 of culture. Morphological integrity ofvillous explants and their EVT differentiation were monitored daily forup to 6 days.

Antisense Oligonucleotides and their Effects on EVT Formation

Phosphorothioate oligonucleotides (ON) were synthesized on a DNAsynthesizer and purified by capillary electrophoresis. Oligonucleotidesof 16 base pairs targeted against sequences adjacent to the AUGinitiation codon of human endoglin (23) mRNA were synthesized. Previousstudies have demonstrated that antisense oligonucleotides, targeted tosequences adjacent to initiation codons, are most efficient ininhibiting translation (24). Furthermore, 16-mer oligonucleotides areshort enough to be taken up efficiently and provide sufficientspecificity for hybridization to the corresponding target mRNA (24). Thesequences of the antisense and sense endoglin oligonucleotides were5′-GCGTGCCGCGGTCCAT-3′ (SEQ ID NO: 3) and 5′-ATGGACCGCGGCACGC-3′ (SEQ IDNO: 4), respectively. An oligomer with the same composition as theantisense oligonucleotide, but with a scrambled sequence,5′-GCGGGCCTCGTTCCAG-3′ (SEQ ID NO: 5), was also synthesized and used asa negative control. Oligonucleotides were dissolved in water and theirconcentration was estimated by optical density at OD₂₆₀. Antisense orsense oligonucleotides (5-10 μM) were added to the villous explants onday 1 and day 3 of culture. EVT sprouting and migration from the distalend of the villous tips were recorded daily for up to 6 days.

Fibronectin Production

Villous explants of 5-8 weeks gestation were incubated overnight inDMEM/F12. Explants were then washed and incubated in DMEM/F12 containingeither 10 μg/ml MAb 44G4 or non-immune IgG, 10 μM antisense, scrambledor sense endoglin oligonucleotides. The medium with or without thevarious agents was changed on day 3 and was replaced on day 5 bymethionine-cysteine free low glucose DMEM containing 25 μCi/ml of[³⁵S]methionine/cysteine with or without the same antibodies oroligonucleotides. The cultures were metabolically labelled for 18 h.Conditioned culture media were collected and diluted with an equalamount of 25 mM Tris-HCl buffer, pH 7.4, 0.15 M NaCl and 0.5% (v/v)Triton® X-100 reagent and fibronectin was isolated usinggelatin-Sepharose® reagent as previously described (25). Briefly, 50 μlof the gelatin-Sepharose® reagent suspension was added to 500 μl ofmedium and the samples were incubated overnight at 4° C. Thegelatin-Sepharose® beads were centrifuged, washed three times inTris/Triton® X-100 buffer and fibronectin was eluted by boiling for 5 mMin 1% (v/v) SDS and electrophoresed on a 4-12% (w/v) polyacrylamidegradient gels. Radiolabeled fibronectin was revealed by autoradiographyand quantitated using a PhosphoImager™ instrument (410A and Image Quantsoftware, Molecular Dynamics).

[³H]Thymidine Incorporation into DNA

Villous explants of 5-8 weeks gestation, cultured for 48 h with andwithout antisense ON to endoglin, were incubated in the presence of 1μCi of [³H]thymidine per milliliter of medium. After 6 h of incubationexplants were washed with PBS, fixed in 4% paraformaldehyde for 1 h,embedded in OCT and processed for cryostat sections as previouslydescribed. Ten micron sections were mounted on3-amino-propyl-tryethoxysilane-precoated slides and coated with NBT-2emulsion (Eastman Kodak, Rochester, N.Y.). Slides were developed after 3days using Kodak D-19® developer, counterstained with eosin and examinedby bright-field microscopy.

Data Analysis

All data are presented as means±s.e.m. of at least three separateexperiments carried out in triplicate. Statistical significance wasdetermined by Student's (t)-test for paired groups and by one-wayanalysis of variance followed by assessment of differences usingStudent-Newman-Keuls test for non-paired groups. Significance wasdefined as p<0.05.

Results Stimulation of EVT Outgrowth and Migration by Antibody andAntisense Oligonucleotides to Endoglin

The morphological examination of villous explants of 5-8 weeksgestation, cultured in serum-free medium, revealed a pattern of EVTdifferentiation (cell outgrowth and migration) similar to that describedby Genbacev et al (21). The viability of the explants, as measured bythe rate of production of progesterone and hCG, remained relativelyconstant for up to 6 days.

The ability of an antibody to endoglin (MAb 44G4) to alter the earlyevents of EVT differentiation along the invasive pathway was examined.Exposure of villous explants of 5-8 weeks gestation to 44G4 IgG wasassociated with an increase in EVT outgrowth from the distal end of thevillous tips and a higher number of cells migrating into the surroundingmatrix. Stimulation of EVT outgrowth and migration by 44G4 IgG wasspecific as incubation of explants with an equivalent amount ofnon-immune murine IgG or medium alone had no effect. Furthermoreaddition of 44D7 IgG (10 μg/ml) reactive with CD98 antigen expressed athigh levels on syncytiotrophoblast (26) had no stimulatory effect.

Antisense endoglin also enhanced the number of EVT outgrowths as well astheir migration and invasion into the Matrigel. Control explants,cultured in the presence of sense endoglin oligonucleotides, exhibitedno such effect.

Further experiments demonstrated that 24 h after the addition of 44G4IgG (day 2 of culture) there was a significant increase in EVT outgrowthand migration from 0.20±0.03 in the control group to 2.03±0.46 in theantibody treated group (n=4; p<0.005). After 5 days of treatment (day 6)the number of EVT outgrowths increased from 0.64±0.09 in controlIgG-treated explants to 3.2±0.5 in the 44G4 IgG-treated explants (n=10,p<0.05). Subsequent experiments demonstrated that the stimulatory effectof 44G4 IgG was dose-dependent and maximal at 1 μg/ml.

The stimulatory effect of antisense endoglin oligonucleotides on EVToutgrowth and migration was observed on day 3 of culture with 6.87±1.5in the antisense-treated group versus 1.42±0.41 in the sense-treatedgroup (p<0.05). After 5 days of exposure, the number of EVT/villous tipincreased from 2.08±0.47 in sense-treated explants to 8.46±1.7 inantisense-treated cultures. The antisense-endoglin effect on trophoblastdifferentiation was specific as incubation of explants with anequivalent amount of either sense endoglin or scrambledantisense-endoglin oligonucleotide (not shown) had no effect. Antisenseendoglin stimulated EVT outgrowth and migration in aconcentration-dependent manner with maximal stimulation observed at 10μM.

Characterization of Trophoblast Differentiation Along the InvasivePathway in Villous Explants Culture

Previous reports indicate that stem trophoblasts within the villous coreand at the proximal site of the column, where trophoblasts start tomigrate away from the stem villi, undergo proliferation (21), whereasdifferentiated EVT do not. Therefore, studies were carried out todetermine if EVT outgrowth triggered by antisense endoglin treatment wasdue to cell division or migration. [³H]Thymidine autoradiography ofexplants exposed to antisense endoglin ON showed villous trophoblastproliferation within the villous tip at the proximal site of the formingcolumn, while both differentiated EVT, which have invaded thesurrounding Matrigel® reagent, and mesenchymal cells in the villous coredid not show any DNA synthesis. This suggests that EVT within the columndo not divide and that blockage of endoglin most likely induces cellmigration from the villous core.

Trophoblast differentiation in situ is accompanied by a temporally andspatially regulated switch in integrin repertoire (4). When placentalexplants of 5-8 weeks gestation were maintained in culture for 5 days inthe presence of antisense-endoglin oligonucleotides, the stimulation ofEVT outgrowth and migration was also accompanied by changes in integrinexpression. The α₆ integrin subunit was found on polarizedcytotrophoblasts within the villi and on the non-polarized trophoblastsin the proximal columns. The α₅ integrin subunit was minimally expressedon polarized trophoblasts or syncytium, but was present on EVT withinthe columns. EVT which had migrated further away in the Matrigel werenegative for the α₅ integrin. All trophoblast cells, including CTBwithin the villi, the syncytiotrophoblast and EVT stained positively forcytokeratin confirming the epithelial-like nature of the cells formingthe columns and migrating into the Matrigel. EVT which have migratedinto Matrigel were positive for the α₁ integrin. A polyclonal antibodyto TGF-β showed staining of the syncytiotrophoblast and stroma of thevilli, suggesting that TGF-β₃ was present in the culture system.Migrating EVT and the Matrigel itself, known to contain TGF-13, showedweak positive staining. No reactivity was observed in the explantsstained with control IgG.

As little EVT outgrowth is observed under basal culture conditions, theexpression of endoglin in trophoblast columns could only be studied inantisense-treated explants. Immunohistochemical analysis of explantstreated with antisense oligonucleotides to endoglin revealed that inintact villi the syncytiophoblast maintained high levels of endoglin.Low levels of endoglin and α₅ integrin were observed in the stroma;however this staining appears non-specific as it was also observed withnon-immune IgG. The staining of endoglin in EVT of explants treated withantisense endoglin was weakly positive when compared to sections of thesame explant stained with control IgG. In addition, endoglin expressionin proximal columns of explants was much reduced when compared tosections of 9 weeks gestation placenta stained under similar conditions.When a subsequent section of this placenta is stained for α₅ integrin,the transition zone in the proximal column is clearly visualized asnegative for α₅, but positive for endoglin. The α₅ integrin in explantstreated with antisense endoglin was also found to be highly expressed inEVT within proximal and distal columns. These data suggest thatantisense endoglin treatment, which promotes EVT outgrowth and migrationin explant cultures, induces a decrease in endoglin expression at thelevel of the transition zone, which is followed by an increase in theexpression of the α₅ integrin fibronectin receptor.

Stimulation of Fibronectin Production by Interference with TGF-βResponse

FN has been localized to specific regions of the matrix surrounding theanchoring villi and its production is increased during EVTdifferentiation (27). Thus the effect of either 44G4 IgG or antisenseendoglin on fibronectin synthesis by villous explants from 5-8 weeksgestation was investigated. Explants were metabolically labelled on day4 with [³⁵S]methionine and newly synthesized FN released into the mediaover a period of 18 h was measured. Both 44G4 IgG and antisense-endoglinoligonucleotides induced a significantly greater production of FN thanthat observed in control IgG or sense oligonucleotide-treated cultures.PhosphoImager™ instrument analysis of all data demonstrated an 8- and5-fold increase in FN synthesis (5 independent experiments carried outin triplicate, p<0.05) for 44G4 IgG and antisense-endoglin treatedexplants, respectively, relative to control sense or DMEM/F12 alone. FNproduction in villous explants, cultured in the presence of a scrambledantisense endoglin oligonucleotide, was similar to that observed insense-treated explants or in medium alone.

To demonstrate that endoglin is an essential component of the receptorcomplex in mediating the effects of TGF-β₁ and TGF-β₃, villous explantswere preincubated with either antisense or antibody to endoglin totrigger EVT differentiation. After an overnight incubation, exogenousTGF-β₁, TGF-β₂ or TGF-β₃ were added at a concentration of 10 ng/ml.Explants were metabolically labelled at day 5 of culture and FNsynthesis was measured. PhosphoImager™ instrument analysis demonstratedthat both antibody and antisense to endoglin significantly stimulated FNsynthesis. Addition of exogenous TGF-β₁ and TGF-β₃ to explant culturesincubated with antisense ON or antibody to endoglin, which binds bothisoforms, did not alter the stimulatory effect of antisense ON andantibody to endoglin on FN synthesis. In contrast, addition of TGF-β₂,which does not interact with endoglin, overcame the antibody andantisense ON stimulatory effect on FN synthesis. TGF-β₂, but not -β₁ and-β₃, inhibited also the EVT outgrowth and migration induced by theantisense endoglin treatment

Discussion

Treatment of human villous explants from 5-8 weeks gestation withantibodies and antisense oligonucleotides to endoglin stimulated EVTdifferentiation along the invasive pathway. This was manifested by 1) asignificant increase in EVT outgrowth and migration, 2) an increase infibronectin production 3) stem villous trophoblast proliferation and 4)a switch in integrin expression similar to that observed in vivo duringformation of anchoring villi. These data suggest that endoglin regulatesEVT differentiation during placental development. Endoglin, which isexpressed in vivo in the transition area where polarized trophoblastsbreak through the syncytium and begin forming columns of non-polarizedcells, appears to be a key molecule in mediating the inhibition oftrophoblast differentiation.

During the first trimester of gestation TGF-β is colocalized with one ofits natural inhibitors, decorin, in the ECM of decidual tissue,suggesting that this proteoglycan may aid TGF-β storage or limit itsactivity within the decidual ECM (12). The findings described hereinsuggest that TGF-β₃ produced by the villi is a negative regulator oftrophoblast differentiation along the invasive pathway. The expressionof endoglin at the transitional zone from polarized to non-polarizedtrophoblasts appears essential to the mediation of this negativeregulation. Blocking endoglin expression in this transition phasetriggers EVT outgrowth and migration and FN production. Thus,trophoblast invasion, characteristic of normal human placentation, isdependent on an intricate balance between positive and negativeregulators. The data herein indicate that endoglin is a criticalnegative regulator of this system. Therefore, inappropriate expressionor function of endoglin may contribute to the major complications ofpregnancy such as preeclampsia or choriocarcinoma, associated withabnormal trophoblast invasion and placenta development.

Example 2

The present experiments were conducted to define the precise componentsthat endogenously regulate trophoblast invasion. Using human villousexplants of 5-7 weeks gestation it was observed that while trophoblastcells remain viable they do not spontaneously invade into thesurrounding matrigel. In contrast, trophoblast cells from 9-13 weeksexplants spontaneously invade the matrigel in association with anupregulation of fibronectin synthesis and integrin switching.Trophoblast invasion at 5-7 weeks can be induced by incubation withantisense to TGF-β₃, TGFβ receptor I (ALK-1) or TGFβ receptor II. Onlyminimal invasion occurred in response to antisense to TGFβ₁ andantisense TGFβ₂ failed to induce invasion. These data suggest thatTGF-β₃ via the ALK-1-receptor II complex is a major regulator oftrophoblast invasion in vitro. To determine whether this system may alsooperate in vivo, immunohistochemical staining was conducted for TGF-β1and -3 and for TGFβ receptor I and II in trophoblast tissue from 5-13weeks of gestation. Strong positive immunoreactivity was observed forTGF-β₃ in both cyto- and syncytiotrophoblast from 5-9 weeks of gestationbut immunoreactivity was markedly reduced by 12-13 weeks. Expression ofTGF-β₁ was absent at 5 weeks, and transiently expressed at around 8weeks of gestation. TGF receptor I and II immunoreactivity was strongbetween 5-8 weeks but was not present at 12-13 weeks. Thus, the presenceof TGF-β₃ and its receptors at 5-8 weeks at a time when there is nospontaneous trophoblast invasion in vitro and the absence of thesemolecules at 12-13 weeks when spontaneous in vitro invasion occurs isconsistent with a major role for TGF-β₃ as an endogenous inhibitor oftrophoblast invasion.

Example 3

Studies were carried out to determine if shallow trophoblast invasion inpreeclampsia was associated with an abnormally sustained inhibition ofinvasion by TGF-β. In particular, the expression/distribution of thedifferent TGF-β isoforms and their receptors was investigated usingimmunohistochemical analysis in normal placentae at 7-9 weeks (at theonset of trophoblast invasion) at 12-13 weeks (the period of peakinvasion), in control placentae between 29 and 34 weeks and inpreeclamptic placentae ranging from 27 to 34 weeks. In normal placentae,TGF-β₃ expression was markedly reduced with advancing gestational age.Expression was high in cyto- and syncytiotrophoblast cells at 7-9 weeksof gestation but was absent in villous tissue at 12-13 weeks and at29-34 weeks of gestation. A similar decline in positive immunoreactivityagainst TGF-β receptor I and II was also observed over this time period.In contrast, in preeclamptic placentae between 27-34 weeks of gestation,strong staining for TGF-β₃ and its receptors was present insyncytiotrophoblast and stromal cells. Immunopositive reactivity was notdetected against TGF-β₁ or TGF-β₂ in either normal or preeclampticplacentae. These data indicates that preeclampsia may result from afailure of trophoblast cells to downregulate expression of TGF-β₃ andits receptors which continue to exert an inhibitory influence ontrophoblast invasion into the uterine wall.

Example 4 Materials and Methods RT-PCR and Southern Blot Analysis

Total RNA was extracted from the placenta, reverse transcribed andamplified by 15 cycles of PCR using TGFβ isoform specific primers.RT-PCR products were analysed by Southern blotting using ³²P-labelledTGFβ cDNAs. The primer set chosen for amplification of TGFβs were basedon human mRNA sequences. Primers used for amplification were: (a) TGF-β₁cDNA: (forward primer): 5′-GCCCTGGACACCAACTATTGCT-3′ (SEQ ID NO: 6),(reversed primer): 5′-AGGCTCCAAATGTAGGGGCAGG-3′ (SEQ ID NO: 7)(predicted product size=161 bp); (b) TGF-β₂ cDNA (forward primer):5′-CATCTGGTCCCGGTGGCGCT-3′ (SEQ ID NO: 8), (reversed primer):5′-GACGATTCTGAAGTAGGG-3′ (SEQ ID NO: 9) (predicted product size=353 bp);(c) TGF-β₃ cDNA: (forward primer): 5′-CAAAGGGCTCTGGTGGTCCTG-3′, (SEQ IDNO: 10) (reversed primer): 5′-CTTAGAGGTAATTCCCTTGGGG-3′ (SEQ ID NO: 11)(predicted product size=374 bp); (c) 13-actin cDNA: (forward primer):5′-CTTCTACAATGAGCTGGGTG-3′, (SEQ ID NO: 12) (reversed primer):5′-TCATGAGGTAGTCAGTCAGG-3′ (SEQ ID NO: 13) (predicted product size=307bp). The identity of the PCR reaction products was also confirmed bysequencing.

Immunohistochemistry

Placental tissue was processed for immunocytochemistry as previouslydescribed (I. Caniggia et al., Endocrinology. 138, 3976 1997). Purifiedrabbit polyclonal antibody directed against TGF-β₁, TGF-β₂ and TGF-β₃(Santa Cruz Biotechnology, Santa Cruz, Calif.) were used at 1:50dilution. Sections (7 μm) were stained using the avidin-biotinimmunoperoxidase method (I. Caniggia et al., Endocrinology. 138, 39761997). Control experiments included replacement of primary antibodieswith antiserum preincubated with an excess of TGFβs (competing peptide)or with blocking solution [5% (vol/vol) NGS and 1% (wt/vol) BSA].

Human Villus Explant Culture System

Villous explant cultures were established as described previously (I.Caniggia et al Endocrinology. 138, 3976 1997, O. Genbacev et al.,Placenta 13:439, 1992) from first trimester human placentae (5-10 weeksgestation) or from preeclamptic and age-matched control placentae (30and 32 weeks of gestation) after collection according to ethicalguidelines. The preeclamptic group was selected according to bothclinical and pathological criteria (L. Chesley, Obstet. Gynecol. 65,423, 1985). Following an overnight period in serum-free DMEM/F12,explants were cultured in media containing antisense or senseoligonucleotides (10 μM) for up to 6 days (with changes ofmedia/oligonucleotides every 48 hours). Phosphorothioateoligonucleotides of 16 base pairs targeted against sequences adjacent tothe AUG initiation codon of different human TGFβ isoforms mRNA weresynthesized as follows: TGF-β₁ 5′-CCCCGAGGGCGGCATG-3′ (SEQ ID NO: 14)and 5′-CATGCCGCCCTCGGGG-3′, (SEQ ID NO: 15) respectively; TGFβ₂5′-CACACAGTAGTGCATG-3′ (SEQ ID NO: 16) and 5′-CATGCACTACTGTGTG-3′ (SEQID NO: 17); TGF-β₃ 5′-CCTTTGCAAGTGCATC-3′ (SEQ ID NO: 1) and5′-GATGCACTTGCAAAGG-3′ (SEQ ID NO: 2).

Fibronectin Synthesis

To measure fibronectin synthesis on day 5 explants were cultured in thepresence of 25 μCi/ml of [³⁵S]methionine/cysteine for 18 hours.Conditioned culture media were collected and diluted with an equalamount of 25 mM Tris-HCl buffer, pH 7.4, 0.15 M NaCl and 0.5% (v/v)Triton® X-100 reagent and fibronectin was isolated usinggelatin-Sepharose® reagent as previously described (I. Caniggia et alEndocrinology. 138, 3976 1997, E. Engvall et al Int. J. Cancer. 20:1,1977). Radiolabeled fibronectin was revealed by autoradiography andquantitated using a PhosphoImager™ instrument (410A and Image Quantsoftware, Molecular Dynamics).

Gelatinolytic Activity

Analysis of gelatinolytic activity was performed using 10%polyacrylamide gel (wt/vol) impregnated with 0.1% gelatin (NOVEX, SanDiego, Calif.) as previously described (I. Caniggia et al Endocrinology.138, 3976 1997). For Western blot analysis of metalloproteasesexpression, 5 μl of conditioned media were subjected to gelelectrophoresis using 10% polyacrylamide gels. Proteins were thenblotted to Westran® PVDF membrane. Primary antibodies were used at 1:100dilution and detected using horse radish peroxidase conjugated antimouseIgG (Amersham 1:10.000 fold dilution) and enhanced by chemiluminescence(ECL, Amersham).

Results:

The expression of TGFβ around 9-12 weeks of pregnancy and itsrelationship to trophoblast invasion and subsequently preeclampsia wereinvestigated. Using low cycle RT-PCR followed by Southern blot analysisall three isoforms of TGFβ were found to be expressed during the firsttrimester (FIG. 3A). However, while transcripts corresponding to TGF-β₁and TGF-β₂ were uniformly expressed throughout this period, theexpression of TGF-β₃ exhibited a striking pattern of developmental ortemporal regulation. TGF-β₃ mRNA levels were relatively low at 5-6weeks, increased markedly between 7 and 8 weeks, and then fellprecipitously at 9 weeks. This pattern of expression for the TGF-β₃isoform was confirmed at the protein level by immunohistochemistry (FIG.3B). TGF-β₃ was localized to cyto and syncytiotrophoblasts within thevillous and also to cytotrophoblasts within the invading column (FIG.3B). TGF-β₃ was noticeably absent in those cytotrophoblast cells at thetransition between polarized and non-polarized cells at the proximalsite of the forming column. Importantly, the down-regulation of TGF-β₃around 9 weeks is temporally associated with the period of maximaltrophoblast invasion in vivo and the expression of markers ofcytotrophoblast invasion, including switching of integrin isoforms(Damsky, C. H. et al Development 120:3657, 1994), synthesis of matrixligands for these integrins (P. Bischof, L. Haenggeli A. Campana, HumanReprod. 10, 734. (1995), M. J. Kupferminc, A. M. Peaceman, T. R. Wigton,K. A. Rehnberg, M. A. Socol, Am. J. Obstet. Gynecol. 172, 649 (1995))and upregulation of gelatinase A (MMP2) and gelatinase B (MMP9) activity(C. I. Librach, et al. J. Biol. Chem. 269, 17125. (1994)).

To determine the functional significance of the TGFβ expressionpatterns, a human villous explant culture system was used which mimicsclosely the normal pattern of trophoblast invasion in vivo (I. Caniggia,C. V. Taylor, J. W. K. Ritchie, S. J. Lye, M. Letarte, Endocrinology.138, 4977 (1997), O. Genbacev, S. A. Schubach, R. K. Miller, Placenta13, 439. (1992)). Morphologic (EVT outgrowth) and biochemical(fibronectin [FN] synthesis and gelatinase activity) indices oftrophoblast invasion were monitored in response to antisense (AS)induced suppression of TGFβ isoform expression in explants at 5-8 weeksof gestation. Explants exposed to AS TGF-β₃ (but not TGFβ₁ or TGFβ₂)displayed prominent EVT outgrowth from the distal end of the villous tip(FIG. 4A). This morphologic response was associated with a significantincrease in FN synthesis (FIG. 4B, and FIG. 4E) and gelatinase activity(FIG. 4D). The specificity of the AS TGF-β₃ response was demonstrated byreversal of both morphologic and biochemical indices when AS-treatedexplants were cultured in the presence of TGF-β₃ but not TGFβ₁ (FIG.4C). The induction of FN synthesis by AS TGF-β₃ at 5-8 weeks was lost at9-13 weeks (FIG. 4E) further demonstrating the specificity of the ASaction as TGF-β₃ is not expressed in villous trophoblast at 9-12 weeks.

These functional data together with the temporal-spatial expressionpatterns strongly suggest that down-regulation of TGF-β₃ around 9-12weeks is required for optimal trophoblast invasion indicate that afailure to down-regulate TGF-β₃ expression is the basis of limitedtrophoblast invasion found in preeclampsia. Significantly higher levelsof mRNA encoding TGF-β₃ (but not TGFβ₁ or TGFβ₂) were found inpreeclamptic versus control placentae (FIG. 5A). Immunoreactive TGF-β₃intensively labelled syncytio and cytotrophoblasts in villous tissuesfrom preeclamptic patients while little or no immunoreactivity waspresent in the age-matched controls (FIG. 5B). Elevated levels of FNmRNA and a failure to complete integrin switching (i.e., the trophoblastremain positive for α₅ and fail to express α₁ were also observed inpreeclamptic placentae. These data suggest that the trophoblasts frompreeclamptic placenta are arrested at a relatively immature phenotypepossibly due to a failure to undergo complete differentiation along theinvasive pathway during the first trimester of gestation.

To determine whether there was functional significance associated withoverexpression of TGF-β₃ in preeclamptic placentae, the pattern oftrophoblast differentiation along the invasive pathway in explants fromcontrol and preeclamptic patients was analyzed. When cultured onmatrigel, explants from non-preeclamptic patients showed formation ofEVT columns which spontaneously invaded into the surrounding matrigel.In contrast, explants from preeclamptic placentae failed to exhibit EVToutgrowth or invasion (FIG. 6A). These data are consistent with the viewthat preeclampsia is associated with reduced invasive capability oftrophoblasts. Of critical importance to the investigation was whetherthis reduced invasive capability was due to the overexpression ofTGF-β₃. Therefore the differentiation of villous explants frompreeclamptic patients cultured in the presence of AS TGF-β₃ wasmonitored. In contrast to untreated or sense-treated controls, treatmentof explants from preeclamptic patients with AS TGF-β₃ restored theinvasive capability, as demonstrated by the formation of EVT columnsmigrating through the matrigel (FIG. 6A). The invasive nature of thisphenotype was confirmed by the finding that explants treated with ASTGF-β₃ acquired the expression of gelatinase B/MMP9, an enzyme which isnormally only expressed in trophoblast cells that are highly invasive(FIG. 6B and FIG. 6C).

The data presented here demonstrate not only that abnormalities inTGF-β₃ expression are associated with preeclampsia but also thatdown-regulation of TGF-β₃ with antisense oligonucleotides restores theinvasive capability of preeclamptic trophoblasts. The data areconsistent with a model of normal placentation in which down-regulationof TGF-β₃ expression in trophoblast around 9 weeks of pregnancy permitsdifferentiation of trophoblast to EVT that form the anchoring villi andfrom which derive the α1-integrin positive EVT which invade deep intothe maternal uterus. This invasion contributes to the remodelling of theuterine spiral arteries and ultimately enables the establishment ofincreased vascular perfusion of the placenta. In placentae predisposedto preeclampsia, TGF-β₃ expression remains abnormally elevated andtrophoblasts remain in a relatively immature state of differentiation.As a direct consequence, trophoblast invasion into the uterus is limitedand uteroplacental perfusion is reduced. This conclusion is consistentwith the clinical manifestations of preeclampsia, including shallowtrophoblast invasion into the uterus and abnormally high uteroplacentalvascular resistance.

Example 5 Role of O₂ Tension in Trophoblast Invasion

The role of oxygen tension in regulating trophoblast differentiationalong the invasive pathway has been investigated. The data indicate thatexpression of hypoxia inducible factor HIF-1α parallels that of TGF-β₃in first trimester trophoblast (i.e. peaks at 6-8 weeks but decreasesafter 9-10 weeks when oxygen tension increases (FIG. 7A). The presenceof putative HIF-1 binding sites in the promoter region of the TGF-β₃gene suggests that induction of HIF-1α by low PO₂ (around 6-8 weeks) upregulates TGF-β₃ transcription and blocks a trophoblast invasion. Afailure of the system to down-regulate at 9-12 weeks (either due to ablock in response to normoxia or the absence of an increase in oxygentension) could lead to shallow invasion and predispose to preeclampsia.This is supported by data showing that expression of HIF-1α isdramatically increased in placentas of preeclamptic patients whencompared to age-matched control tissue (FIG. 7B). In FIGS. 7A and 7BmRNA HIF-1α expression was assessed by using low cycle RT-PCR followedby Southern blot analysis. This is also supported by FIG. 8 showing theeffect of low oxygen tension of TGF-β₃ and HIF-1α expression in villousexplants; FIG. 9 showing the effect of low oxygen tension on villousexplant morphology; and FIG. 10 showing the effect of antisense toHIF-1α on villous explant morphology.

Example 6 TGF-β₃ Signals Through a Receptor Complex

In addition to endoglin, evidence indicates that TGF-β₃ signals througha receptor complex which includes RI (ALK-1) and RII. While TGFβ R-I(ALK-5) and TGFβ R-II are expressed throughout the villi and decidua at9-10 weeks gestation; they are absent from the base of the proximalcolumns of the anchoring villi at the transition zone between thevillous and the invading EVT, exactly at the site where endoglin isunregulated. This dramatic change in TGF-β receptor expression suggeststhat EVTs within the columns in situ are not subject to the inhibitoryactions of TGFβ but via R-I and R-II they do come under the control ofthis ligand upon entering the decidua. The potential clinical importanceof the TGFβ receptor system in trophoblast invasion is highlighted bydata demonstrating that beside TGF-β₃, R-I is expressed at greaterlevels in trophoblast tissue of preeclamptic patients when compared tothat in age-matched control placenta. Antisense disruption of R-I(ALK-1) and R-II expression stimulated trophoblast outgrowth/migrationand FN synthesis. In contrast, antisense to R-I (ALK-5) inhibited FNsynthesis.

While the present invention has been described with reference to whatare presently considered to be the preferred examples, it is to beunderstood that the invention is not limited to the disclosed examples.To the contrary, the invention is intended to cover variousmodifications and equivalent arrangements included within the spirit andscope of the appended claims.

All publications, patents and patent applications are hereinincorporated by reference in their entirety to the same extent as ifeach individual publication, patent or patent application wasspecifically and individually indicated to be incorporated by referencein its entirety.

Below full citations are set out for the references referred to in thespecification and detailed legends for the figures are provided.

FULL CITATIONS FOR REFERENCES REFERRED TO IN THE SPECIFICATION

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DETAILED FIGURE LEGENDS

-   FIG. 3 Expression of TGF-β isoforms in human placenta in the first    trimester of gestation. (FIG. 3A) Message expression of TGFβ    isoforms was assessed by low cycle RT-PCR followed by Southern blot    analysis using specific probes for TGF-β₁, TGF-β₂ and TGF-β₃ and the    control house-keeping gene β-actin. Note that TGF-β₃ expression    increases around 7-8 weeks gestation and declines thereafter. (FIG.    3B) Immunoperoxidase staining of TGF-β₃ was performed in placental    sections at 5, 8 and 12 weeks of gestation. Sections of placental    tissue of 5 weeks gestation show positive immunoreactivity    visualized by brown staining in the cytotrophoblast,    syncytiotrophoblast and stromal cells of the chorionic villi.    Sections of placental tissue of 8 weeks gestation show strong    positive immunoreactivity in the cytotrophoblast,    syncytiotrophoblast, and stromal cells. Note that TGF-β₃ was    expressed in the non-polarized trophoblast within the column (EVT,    thin arrow) but was absent in the transitional zone where polarized    cells become unpolarized (thick arrows). Sections of placenta at 12    weeks gestation demonstrate low or absent TGF-β₃ immunoreactivity in    the villi. There is no immunoreactivity when antiserum was    preincubated with an excess of TGF-β₃ competing peptide (8 weeks,    control).-   FIG. 4 Antisense TGF-β₃ stimulates trophoblast migration,    fibronectin production and gelatinase activity. Explants of 5-8    weeks gestation were treated for 5 days with 10 μM antisense    oligonucleotides to TGF-β₃ (AS-β3), AS-β3 plus 10 ng/ml recombinant    TGF-β₃ (AS-β3+β3) or AS-β3 plus recombinant TGF-β₁ (AS-β3+β1).    Control experiments were run in parallel using sense TGF-β₃ (S-β3)    or medium alone (FIG. 4C). (FIG. 4A) Shown is a representative    experiment demonstrating that addition of recombinant TGF-β₃ to    antisense TGF-β₃ treated explants (AS-β3+β3) abolishes the antisense    stimulatory effect on trophoblasts budding and outgrowth (arrows).    (FIG. 4B) Similar reversal effect on AS-β3 stimulatory effect by    exogenous TGF-β₃ was demonstrated also for fibronectin synthesis.    Representative analysis of triplicate samples from a single    experiment is shown. The position of the marker with M_(r)=200×10³    is indicated. Lanes 1-3, S-β3 treated explants; lanes 4-6, AS-β3    treated explants; lanes 7-9, AS-β3+β3 treated explants. (FIG. 4C)    Changes in fibronectin estimated after normalization to control    cultures. Antisense TGF-β₃ treatment (AS-β3, solid bar)    significantly increased (p<0.05; one-way ANOVA followed by    Student-Newman-Keuls test for non-paired groups) the amount of    labelled fibronectin compared to both medium alone (FIG. 4C, open    bar) or sense (S-β3, cross bar). Addition of exogenous TGF-β₃    (AS-β3+β3 squares bar) but not TGF-β₁ (AS-β3+β1 cross hatched bar)    to the antisense treated explants abolished the antisense    stimulatory effect on fibronectin production demonstrating the    specificity of the action of TGF-β₃. (FIG. 4D) Gelatinase activity    in conditioned media of explants treated with sense or antisense    oligonucleotides to TGF-β3. Arrows indicate positions of gelatinases    activity (MMP2: 60, 68; MMP9: 84 and 92, kDa). (FIG. 4E) The    antisense TGF-β₃ stimulatory effect on fibronectin production is    lost after 9 weeks of gestation. Explants of 6 and 10 weeks    gestation were treated with 10 μM antisense (AS-β3) or control sense    (S-β3) oligonucleotides to TGF-β₃. Newly synthesized fibronectin was    isolated from the medium as described above. Representative analysis    of triplicate samples from a single experiment is shown. Lanes 1-3    and 7-9, S-β3 treated explants; lanes 4-6 and 10-12, AS-β3 treated    explants.-   FIG. 5 TGF-β₃ is overexpressed in preeclamptic placentae. (FIG. 5A)    Message expression of TGFβ isoforms, α₅ integrin receptor and    fibronectin in preeclamptic (PE) and age-matched control placentae    (FIG. 5C) was assessed by low cycle RT-PCR followed by Southern blot    analysis using specific probes for TGF-β₁, TGF-β₂, TGF-β₃, α₅,    fibronectin and the control house-keeping gene β-actin. Note that    TGF-β₃, α₅ and fibronectin, but not TGF-β₁ or TGF-β₂, expression    were higher in preeclamptic placentae when compared to age-matched    control. (FIG. 5B) Immunoperoxidase staining of TGF-β₃ was performed    in placental sections from normal pregnancies and pregnancies    complicated by preeclampsia. Sections of normal placental tissue of    29, 31 and 33 weeks of gestation show low/absent TGF-β₃    immunoreactivity in cells of the chorionic villi. Sections of    preeclamptic placental tissue of the same gestation show strong    positive immunoreactivity visualized by brown staining in the    cytotrophoblast, syncytiotrophoblast and stromal cells of the    chorionic villi. Control experiments were performed using antiserum    preabsorbed with an excess of peptide.-   FIG. 6A Antisense oligonucleotides to TGF-β₃ induce the formation of    columns of trophoblast cells in preeclamptic villous explants.    Villous explant cultures were prepared from preeclamptic and    age-matched control placentae. Explants were maintained in culture    in the presence of either control sense or antisense    oligonucleotides to TGF-β₃ for 5 days. Morphological integrity was    recorded daily. Explants from normal placenta (32 weeks), exposed to    sense oligonucleotides (S-β3) spontaneously form columns of    trophoblast cells which migrate and invade into the surrounding    Matrigel (arrows), while explants from preeclamptic placenta (32    weeks) exposed to sense oligonucleotides do not. In contrast,    antisense treatment (AS-β3) triggers the formation of invading    trophoblast columns (arrows) in preeclamptic placentae.

FIG. 6B and FIG. 6C. Antisense oligonucleotides to TGF-β₃ triggersgelatinase activity and expression in preeclamptic villous explants.Explants of 32 weeks gestation from preeclamptic placentae were treatedwith antisense (AS-β3) or control sense (S-β3) oligonucleotides toTGF-β₃ for 5 days. Samples of conditioned medium were collected at day 5and subjected to analysis by gelatin Zymography (FIG. 6B) or Westernblotting with MMP9 antisera (FIG. 6C). Arrows indicate positions ofgelatinases activity (MMP-2: 60, 68; MMP-9: 84 and 92, kDa).

1. A method for diagnosing in a subject a condition requiring regulationof trophoblast invasion comprising detecting TGF-β3, receptors ofcytokines of the TGFβ family, or HIF-1α in a sample from the subject. 2.A method as claimed in claim 1 for diagnosing increased risk ofpreeclampsia in a subject comprising detecting TGF-β₃, receptors ofcytokines of the TGFβ family, or HIF-1α in a sample from the subject. 3.A method as claimed in claim 2 which comprises (a) collecting a samplefrom the subject; (b) measuring the levels of TGF-β₃, receptors ofcytokines of the TGFβ family, or HIF-1α in the sample; and (c) comparingthe levels of TGF-β₃, receptors of cytokines of the TGFβ family, orHIF-1α in the sample to the levels in women with normal pregnancies. 4.A method as claimed in claim 3 wherein the levels of TGF-β₃, receptorsof cytokines of the TGFβ family, or HIF-1α are measured in a sample fromthe subject during the first trimester of pregnancy.
 5. A method asclaimed in claim 1, wherein the receptors of cytokines of the TGFβfamily are selected from the group consisting of TGF-β type I receptor(ALK-I)(RI), TGF-β type II receptor (R-II), endoglin, betaglycan andactivin.
 6. A method for diagnosing or monitoring a pregnancycomplication in a subject, the method comprising a) detecting a level ofa nucleic acid sequence encoding a protein selected from the groupconsisting of TGF-β₃, TGF-β type I receptor (ALK-I)(RI), TGF-β type IIreceptor (R-II), and endoglin in a fluid sample from the subject; and b)comparing the level detected in the subject's sample to a control levelobtained from one or more samples of the same fluid in one or morepregnant controls who did not develop the complication; wherein anincreased level of TGF-β₃, TGF-β type I receptor (ALK-I)(RI), TGF-β typeII receptor (R-II), or endoglin in the fluid sample from the subjectover that of a control level indicates an increased risk of developingthe complication.
 7. The method according to claim 6, wherein thecomplication is a condition or an increased risk of a condition selectedfrom the group consisting of intrauterine growth restriction, molarpregnancy, preterm labour, preterm birth, preeclampsia, fetal anomaly,and placental abruption.
 8. A method for diagnosing an increased risk ofpreeclampsia, in a subject, the method comprising a) contacting a fluidsample from a pregnant subject with a diagnostic reagent that measures alevel of a nucleic acid encoding a protein selected from the groupconsisting of TGF-β₃, TGF-β type I receptor (ALK-I)(RI), TGF-β type IIreceptor (R-II), and endoglin; and b) diagnosing an increased risk ofpreeclampsia in the subject based upon an increased level of one or moreof TGF-β₃, TGF-β type I receptor (ALK-I)(RI), TGF-β type II receptor(R-II), and endoglin in the sample (a) from the subject over that of afluid sample obtained from the same subject at an earlier time in thepregnancy.
 9. The method according to claim 8, wherein steps (a) and (b)are repeated throughout the pregnancy.
 10. A diagnostic kit fordiagnosing or monitoring a pregnancy complication in a subjectconsisting of a reagent that can measure, directly or indirectly, thelevels of endoglin, or a nucleic acid sequence encoding endoglin, and areagent that can measure, directly or indirectly, one or more of TGF-β₃,TGF-β type I receptor (ALK-I)(RI), and TGF-β type II receptor (R-II) ora nucleic acid sequence encoding one or more of TGF-β₃, TGF-β type Ireceptor (ALK-I)(RI), and TGF-β type II receptor (R-II); and one or morepositive or negative controls for each measurement obtained frompregnant controls not having the pregnancy complication.
 11. The kitaccording to claim 10, wherein the complication is a condition or anincreased risk of a condition selected from the group consisting ofintrauterine growth restriction, molar pregnancy, preterm labour,preterm birth, preeclampsia, fetal anomaly, and placental abruption.